A semiconductor device includes a first channel region disposed over a substrate, and a first gate structure disposed over the first channel region. The first gate structure includes a gate dielectric layer disposed over the channel region, a lower conductive gate layer disposed over the gate dielectric layer, a ferroelectric material layer disposed over the lower conductive gate layer, and an upper conductive gate layer disposed over the ferroelectric material layer. The ferroelectric material layer is in direct contact with the gate dielectric layer and the lower gate conductive layer, and has a U-shape cross section.

Provided is a metal gate structure and related methods that include forming a first fin and a second fin on a substrate. In various embodiments, the first fin has a first gate region and the second fin has a second gate region. By way of example, a metal-gate line is formed over the first and second gate regions. In some embodiments, the metal-gate line extends from the first fin to the second fin, and the metal-gate line includes a sacrificial metal portion. In various examples, a line-cut process is performed to separate the metal-gate line into a first metal gate line and a second gate line. In some embodiments, the sacrificial metal portion prevents lateral etching of a dielectric layer during the line-cut process.

Disclosed are semiconductor devices and methods of manufacturing the same. The semiconductor device comprises a first transistor on a substrate, and a second transistor on the substrate. Each of the first and second transistors includes a plurality of semiconductor patterns vertically stacked on the substrate and vertically spaced apart from each other, and a gate dielectric pattern and a work function pattern filling a space between the semiconductor patterns. The work function pattern of the first transistor includes a first work function metal layer, the work function pattern of the second transistor includes the first work function metal layer and a second work function metal layer, the first work function metal layer of each of the first and second transistors has a work function greater than that of the second work function metal layer, and the first transistor has a threshold voltage less than that of the second transistor.

A semiconductor having a first gate-all-around (GAA) transistor, a second GAA transistor, and a third GAA transistor is provided. The first (GAA) transistor includes a first plurality of channel members, a gate dielectric layer over the first plurality of channel members, a first work function layer over the gate dielectric layer, and a glue layer over the first work function layer. The second GAA transistor include a second plurality of channel members, the gate dielectric layer over the second plurality of channel members, and a second work function layer over the gate dielectric layer, the first work function layer over and in contact with the second work function layer, and the glue layer over the first work function layer. The third GAA transistor includes a third plurality of channel members, the gate dielectric layer over the third plurality of channel members, and the glue layer over the gate dielectric layer.

A semiconductor device and method of forming the same including a plurality of vertically aligned semiconductor channel layers disposed above a substrate layer, a gate stack formed on, and around the vertically aligned semiconductor channel layers and source and drain elements disposed in contact with sidewalls of the vertically aligned semiconductor channel layers. An uppermost vertically aligned semiconductor channel layer has a first thickness of semiconductor material and the remaining vertically aligned semiconductor channel layers have a second thickness of semiconductor material different from the first thickness.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate including an array area and a peripheral area adjacent to the array area, a first gate structure positioned in the array area, and a second gate structure positioned in the peripheral area. A width of the first gate structure is less than a width of the second gate structure, and a depth of the first gate structure is less than a depth of the second gate structure.

A method for fabricating semiconductor device includes the steps of: forming a gate structure on a substrate; forming an interlayer dielectric (ILD) layer around the gate structure; performing a replacement metal gate (RMG) process to transform the gate structure into a metal gate; forming an inter-metal dielectric (IMD) layer on the metal gate; forming a metal interconnection in the IMD layer; and performing a high pressure anneal (HPA) process for improving work function variation of the metal gate.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate including an array area and a peripheral area adjacent to the array area, a first gate structure positioned in the array area, and a second gate structure positioned in the peripheral area. A width of the first gate structure is less than a width of the second gate structure, and a depth of the first gate structure is less than a depth of the second gate structure.

Gate stacks for improving integrated circuit device performance and methods for fabricating such gate stacks are disclosed herein. An exemplary gate stack includes a gate dielectric layer disposed over the substrate, a multi-function layer disposed over the gate dielectric layer, and a work function layer disposed over the multi-function layer. The multi-function layer includes a first metal nitride sub-layer having a first nitrogen (N) concentration and a second metal nitride material with a second metal nitride sub-layer having a second N concentration. The second metal nitride sub-layer is disposed over the first metal nitride-sub layer and the first N concentration is greater than the second N concentration. In some implementations, the second N concentration is from about 2% to about 5% and the first N concentration is from about 5% to about 15%.

A semiconductor device and method of manufacturing are provided. In an embodiment a first nucleation layer is formed within an opening for a gate-last process. The first nucleation layer is treated in order to remove undesired oxygen by exposing the first nucleation layer to a precursor that reacts with the oxygen to form a gas. A second nucleation layer is then formed, and a remainder of the opening is filled with a bulk conductive material.